Driving device for a light-emitting component and a method for driving a light-emitting component

ABSTRACT

The invention pertains to a driving device, for a light-emitting component, which can be universally used and is user-friendly. The driving device for a light-emitting component, particularly for a laser, includes an interface device for inputting a control signal selecting an operating mode of the component. It further includes a control device connected to the interface device, which drives the component with a predetermined operating-mode and temperature-dependent bias current and/or a predetermined operating-mode and temperature-dependent modulation current depending on the operating mode selected and depending on the temperature present at the component or on a temperature proportional thereto.

[0001] Driving device for a light-emitting component and a method for driving a light-emitting component.

[0002] The invention relates to a driving device for driving a light-emitting component, particularly a laser.

[0003] The invention is based on the object of specifying a driving device for a light-emitting component which, in particular, can be used universally and, at the same time, exhibits a high degree of user friendliness.

[0004] According to the invention, this object is achieved by a driving device having the features as claimed in claim 1.

[0005] Advantageous developments of the driving device according to the invention are described in the subclaims.

[0006] Accordingly, according to the invention, a driving device for a light-emitting component, particularly for a laser, comprising an interface device for inputting control signals is provided. The control signals are used for selecting an operating mode of the light-emitting component. A control device connected to the interface device selects, depending on the operating mode selected at the interface and depending on the temperature present at the component—or depending on a temperature proportional to the component temperature, a corresponding or matching bias current value and/or modulation current value and applies to the light-emitting component a bias current and/or modulation current which corresponds to the selected bias current value or the selected modulation current value.

[0007] A significant advantage of the driving device according to the invention can be seen in the fact that it provides at least two different operating modes which can be selected by the user by applying corresponding control signals to the interface device. The driving device according to the invention can be used quite universally due to this possibility of selecting the operating mode.

[0008] A further essential advantage of the driving device according to the invention consists in that temperature changes which, as is known, can have a considerable influence on the characteristic of light-emitting components, are automatically taken into consideration by the driving device because the driving takes place both in dependence on the selected operating mode and in dependence on the prevailing temperature.

[0009] A temperature control can be effected in a particularly simple and thus advantageous manner if the driving device exhibits a temperature sensor by means of which the temperature of the light-emitting component or a temperature proportional thereto is measured.

[0010] For example, the temperature control can be effected “indirectly” in that the temperature drift of an amplifier circuit contained in the control device or the temperature characteristic of a thermally sensitive component—for example a temperature-dependent resistor—is used (as temperature sensor).

[0011] The driving device advantageously exhibits a storage device in which in each case a drive table is stored at least for two different operating modes of the light-emitting component, each of the drive tables in each case containing a bias current value and/or a modulation current value for at least two measured temperature values.

[0012] The storage device is preferably connected to the control device; the control device is then constructed, for example, in such a manner that it reads out the in each case associated bias current value and/or modulation current value, stored in the drive table, depending on the selected operating mode and depending on the measured temperature value of the temperature sensor, and drives the component with a bias current corresponding to the bias current value and/or a modulation current corresponding to the modulation current value.

[0013] According to an advantageous embodiment of the driving device according to the invention, it is provided that the temperature sensor is connected to the storage device and the measured temperature value of the temperature sensor is transferred from the temperature sensor to the storage device. The storage device is constructed in such a manner that it exclusively transfers to the control device those bias current values and/or modulation current values which correspond to the respective measured temperature value. In this embodiment of the storage device, the “temperature correction” in the drive to the light-emitting component is thus ensured on the side of the storage device. Thus, the control device can only read out the bias current values or modulation current values corresponding to the in each case prevailing temperature for the individual operating mode from the storage device.

[0014] In order to ensure that the driving device can be adapted to various operating modes in a particularly simple and thus advantageous manner, it is considered to be advantageous if the storage device exhibits a separate storage area for each drive table, particularly in each case a separate memory chip. Thus, the driving device can be adapted very simply to the operating modes desired in each case by changing storage areas or chips by addressing a suitable storage area or connecting a suitable memory chip to the storage device depending on the desired operating mode.

[0015] In addition, it is considered to be advantageous if the temperature sensor is in each case connected to each storage area or memory chip of the storage device. If the temperature sensor, for example, outputs a digital output signal as output signal, this digital output signal can be used directly or indirectly for determining the memory space or memory cell in which the bias current value or modulation current value, belonging to the respective temperature, for the light-emitting component is stored. In this case, therefore, the output signal of the temperature sensor directly specifies the associated memory location at which the desired information for driving the light-emitting component is stored.

[0016] Correspondingly, the storage areas or memory chips in each case preferably have a connection at which the output signal of the temperature sensor can determine the storage area which should be readable by the control device.

[0017] According to another advantageous development of the driving device according to the invention, it is provided that the control device is connected to the temperature sensor and the measured temperature value is transferred from the temperature sensor to the control device. In this embodiment of the invention, the control device, therefore, reads out the respective measured temperature value of the temperature sensor and then accesses, individually for each operating mode, the corresponding storage cells of the storage device in which the current values, that is to say modulation current value and/or bias current value matching the respective measured temperature value and the respective operating mode, are stored.

[0018] In a particularly simple and thus advantageous manner, a light-emitting component can be driven by means of the driving device if the control device comprises an A/D converter and a driver which is connected to the light-emitting component. The driver then drives the light-emitting component with a modulation current and/or a bias current which is predetermined by the A/D converter of the control device. The driver preferably contains an operational amplifier since operational amplifiers have a very high impedance at the input and have a very low current consumption. The A/D converter of the control device is preferably connected to an input of the operational amplifier.

[0019] To ensure that there are other possibilities for the user to influence the driving of the light-emitting component, it is considered to be advantageous if the other input of the operational amplifier is connected to the programmable resistor network which can be controlled by control signals and/or control bits. The electrical characteristic of the operational amplifier can then be adjusted or influenced by applying corresponding control signals or control bits to the programmable resistor network.

[0020] If, for example, it should be possible for the user to influence or correct the “feedback path” formed by a monitor diode of the light-emitting component, it is considered to be advantageous if the programmable resistor network is connected to a monitor diode of the light-emitting component.

[0021] The operational amplifier of the control device is preferably connected in such a manner that the A/D converter of the control device is connected to the negative input of the operational amplifier and the programmable resistor network is connected to the positive input of the operational amplifier.

[0022] The light-emitting component can be, for example, light-emitting diodes, edge-emitting lasers or surface-emitting lasers.

[0023] In addition, the invention is based on the object of specifying a method for driving a light-emitting component which can be used quite universally and is very user friendly.

[0024] According to the invention, this object is achieved by a method having the features of claim 16.

[0025] Advantageous embodiments of the method according to the invention are specified in the subclaims.

[0026] With respect to the advantages of the method according to the invention and its advantageous embodiments, reference is made to the above statements in conjunction with the driving device according to the invention. To explain the invention,

[0027]FIG. 1 shows a first exemplary embodiment of a driving device according to the invention by means of which the method according to the invention can also be carried out and

[0028]FIG. 2 shows an exemplary embodiment of a driver for the driving device according to FIG. 1.

[0029]FIG. 1 shows a driving device 10 which comprises a temperature sensor 20, a storage device 30, an interface device 40 and a controller 50.

[0030] The storage device 30 has a first memory chip 100, a second memory chip 110 and a third memory chip 120. In each of the memory chips 100, 110 and 120, respectively, a drive table is in each case stored which specifies how a laser 200 connected to the drive device 10 is to be driven.

[0031] The memory chips 100, 110 and 120 in each case have a temperature input which is connected to an output A20 of the temperature sensor 20. The temperature inputs of the three memory chips 100, 110 and 120 bear the reference designations T100, T110 and T120, respectively, in FIG. 1.

[0032] The controller 50 has a multiplexer 200, the multiplexer inputs E200 a, E200 b and E200 c of which are connected to outputs of the memory chips 100, 110 and 120. Actually, one input E200 a of multiplexer 200 is connected to the output A100 of the memory chip 100. A further input E200 b of multiplexer 200 is connected to an output A110 of memory chip 110. An additional input E200 c of multiplexer 200 is preceded by an output A120 of memory chip 120.

[0033] In addition, the multiplexer 200 has a control input S200 which is connected to an output A40 of the interface device 40. The interface device 40 is formed by a controller, the input E40 of which forms the interface E10 of the driving device 10 to the outside. Applying corresponding control signals or control bits to input E40 of the interface device 40 allows control signals for driving the multiplexer 200 to be fed into the driving device 10.

[0034] An output A200 of multiplexer 200 is connected to an input E300 of an A/D (analog/digital) converter which is followed by an input E400 of a driver 400. The output A400 of the driver 400 is connected to the laser 150.

[0035] The driving device 10 according to FIG. 1 is operated as follows:

[0036] Firstly, a drive table which specifies how the laser 150 is to be driven in accordance with a first operating mode is stored in the first memory chip 100. The drive table contains in each case a bias current value I _(B) and a modulation current value I _(M) for at least two temperature values. The drive table advantageously exhibits not only current values for two temperature values but for a multiplicity of temperature values. The greater the number of temperature values stored in the drive table, the better the laser 150 can be controlled in the case of temperature changes.

[0037] A drive table is also stored in memory chip 110. This drive table, however, is provided for another operating mode than the drive table which is stored in the first memory chip 100. The drive table in the second memory chip 110 also contains bias current values I _(B) and modulation current values I _(M) which are in each case associated with temperature values. Thus, temperature-dependent drive parameters which can be used for driving the laser 150 can also be taken from the drive table of the second memory chip 110.

[0038] The third memory chip 120 correspondingly also contains a drive table in which bias current values I _(B) and modulation current values I _(M) are stored for various temperature values. The drive table of the third memory chip 120 refers to a third operating mode of the laser 150 which differs from the operating modes stored in the drive tables of the two memory chips 100 and 110.

[0039] When the driving device 10 is taken into operation, the temperature sensor 20 will output at its output A20 a temperature value which specifies the respective temperature of the laser 150 or a temperature proportional thereto. This temperature value T passes to the temperature inputs T100, T110 and T120 of the three memory chips 100, 110 and 120.

[0040] The memory chips 100, 110 and 120 are designed in such a manner that the temperature value T present at the respective temperature input T100, T110 and T120, respectively, directly specifies a storage area or a storage cell which can be read out at the output via outputs A100, A110 or A120, respectively.

[0041] If then an operating mode B is specified from the outside via the interface device 40, the interface device 40 generates an operating mode control signal SB specifying the respective operating mode. This operating mode control signal SB is transferred to the control input S200 of the multiplexer 200 which thereupon selects one of the three memory chips 100, 110 or 120, respectively. Thus, the respective memory chip is selected by the operating mode control signal SB.

[0042] As explained above, the memory chips 100, 110 and 120 in each case contain a drive table which has been predetermined for in each case one operating mode. If, for example, the operating mode control signal SB contains the information that the first operating mode has been selected, the multiplexer 200 will access memory chip 100 in which the drive table for the first operating mode is stored.

[0043] The multiplexer 200 will correspondingly access the second memory chip 110, the drive table of which contains the drive parameters for the second operating mode, if the second operating mode has been selected.

[0044] If the operating mode control signal SB specifies the third operating mode, the multiplexer 200 will address memory chip 120 in which the drive table and operating parameters for the third operating mode are stored.

[0045] In the text which follows, it is assumed that the first operating mode has been selected. The multiplexer 200 will, therefore, address or read out the first memory chip 100. It is only possible to read out the storage area which is predetermined by the measured temperature value T present at the temperature input T100. The multiplexer 200 will thus read out a bias current value I _(B) and a modulation current value IM which corresponds to the first operating mode at the temperature T detected by the temperature sensor 20.

[0046] Multiplexer 200 forwards the current values I _(B) and I _(M) to the A/D converter 300 which generates an analog drive signal UM for the driver 400 from the digital current values I _(B) and I _(M). At output A400 of the driver 400, an output voltage or output potential is then provided which generates the desired bias current I _(B) and the desired modulation current I _(M) in the laser 150.

[0047] The multiplexer 200 will correspondingly access the drive table stored in the second memory chip 110 if the second operating mode is predetermined via the interface device 40. If the third operating mode is required, the drive table in the third memory chip 120 is accessed.

[0048]FIG. 2 shows an exemplary embodiment of the driver 400 according to FIG. 1.

[0049] It can be seen in FIG. 2 that input E400 of the driver 400 is formed by a positive input of an operational amplifier 600. The negative input of the operational amplifier 600 is connected to a terminal 610 of a programmable resistor network R_(Adj), the other terminal 620 of which is connected to ground.

[0050] Moreover, the negative input of the operational amplifier 600 is connected to a monitor diode 700 of the laser 150, which is connected to the supply voltage V_(DD). The monitor diode 700 generates a monitor current I_(MOD) which flows to ground via the programmable resistor network R_(Adj).

[0051] Depending on the voltage U dropped across the programmable resistor network R_(Adj), a potential difference ΔU which is corrected to “0” by the operational amplifier occurs between the two inputs of the operational amplifier 600. This correction leads to an output voltage U_(A) at the output of the operation amplifier 600 which is present as base-emitter voltage at a transistor T1. The collector terminal of transistor T1 is connected to the laser 150 so that the laser 150 is driven by the operational amplifier 600 by means of transistor T1.

[0052] The programmable resistor network R_(Adj) can be, for example, a resistor network as described in detail in the patent application (US Attorney: please refer to IT545 US Application), particularly in conjunction with FIGS. 3 to 5.

[0053]FIG. 3 shows a further exemplary embodiment of a driving device 10. In distinction from the driving device 10 according to FIG. 1, the temperature sensor 20 in the exemplary embodiment of FIG. 3 is connected directly to the control device (40), namely with a microprocessor 800 of the control device 40. This microprocessor 800 replaces the multiplexer 200 as described in conjunction with FIGS. 1 and 2.

[0054] Microprocessor 800 has the task of reading out the temperature sensor 20 and correspondingly reading out the storage device 30 depending on the operating mode B predetermined at the interface via interface 40 and depending on the measured temperature value T determined by the temperature sensor 20.

[0055] In the storage device 30, the drive tables 900, 910, 920 (designated as registers set I to III in FIG. 3) required for driving the laser 150 are stored.

[0056] As soon as the microprocessor has read out the current values I _(B) and I _(M), required for driving the laser 150, from the storage device 30, it correspondingly drives the A/D converter 300 in such a manner that the desired current flows through the laser 150.

[0057] List of Reference Designations

[0058]10 Driving device

[0059]20 Temperature sensor

[0060]30 Storage device

[0061]40 Interface device

[0062]50 Control device

[0063]100 First memory chip

[0064]110 Second memory chip

[0065]120 Third memory chip

[0066]150 Laser

[0067]200 Multiplexer

[0068]300 A/D converter

[0069]400 Driver

[0070]600 Operational amplifier

[0071]610, 620 Terminals of the programmable resistor network

[0072]700 Monitor diode

[0073]800 Microprocessor

[0074]900 Drive table

[0075]910 Drive table

[0076]920 Drive table

[0077] R_(Adj) Programmable resistor network

[0078] T1 Transistor

[0079] I_(B) Bias current

[0080] I_(M) Modulation current

[0081] I_(MOD) Monitor current

[0082]I _(B) Bias current value

[0083]I _(M) Modulation current value 

1. A driving device (10) for a light-emitting component, particularly for a laser (150), comprising an interface device (40) for inputting a control signal (SB) selecting an operating mode of the component (150), and a control device (40) connected to the interface device (40), which, depending on the selected operating mode (B) and depending on the temperature present at the component (150) or on a temperature proportional thereto, drives the component with a predetermined operating-mode- and temperature-dependednt bias current (I_(B)) and/or a predetrmined operating-mode- and temperature-dependent modulation current (I_(M)).
 2. The driving device as claimed in claim 1, wherein the driving device exhibits a temperature sensor (20) which measures the temperature (T) of the component (150) or a temperature proportional thereto, forming a measured temperature value.
 3. The driving device as claimed in claim 1 or 2, wherein the driving device exhibits a storage device (30) in which in each case a drive table is stored at least for two different operating modes (B) of the component (150), each drive table containing a bias current value and/or a modulation current value for at least two temperature values.
 4. The driving device as claimed in claim 1, 2 or 3, wherein the storage device (30) is connected to the control device (40) and the control device (10) is designed in such a manner that it reads out the in each case associated bias current value (I _(B)) and/or modulation current value (I _(M)), stored in the drive table, depending on the selected operating mode (B) and depending on the temperature, and drives the component with a bias current (I_(B)) corresponding to the bias current value and/or a modulation current (I_(M)) corresponding to the modulation current value (I _(M)).
 5. The driving device as claimed in one of the preceding claims, wherein the temperature sensor (20) is connected to the storage device (30) and the respective measured temperature value (T) is transferred from the temperature sensor (20) to the storage device (30).
 6. The driving device as claimed in the preceding claims, wherein the storage device (30) exhibits in each case a separate storage area, particularly in each case a separate memory chip (100, 110, 120), for each drive table.
 7. The driving device as claimed in claim 6, wherein the temperature sensor (20) is in each case connected to each storage area (100, 110, 120) of the storage device (30).
 8. The driving device as claimed in claim 6 or 7, wherein the storage areas (100, 100, 120) are designed in such a manner that the measured temperature value of the temperature sensor (20) in each case specifies the storage area which can be read out by the control device (40).
 9. The driving device as claimed in one of claimed 1 to 4, wherein the control device (20) is connected to the temperature sensor (20) and the respective measured temperature value (T) is transferred from the temperature sensor (20) to the control device (40).
 10. The driving device as claimed in one of the preceding claims, wherein the driving device (40) comprises an A/D converter (300) and a driver (400) which is connected to the light-emitting component (150).
 11. The driving device as claimed in claim 10, wherein the driver (400) exhibits an operational amplifier (600).
 12. The driving device as claimed in claim 11, wherein the A/D converter (300) is connected to one input of the operational amplifier (600).
 13. The driving device as claimed in claim 11 or 12, wherein the other input of the operational amplifier (600) is connected to a programmable resistor network (R_(Adj)) which can be controlled by control signals and/or control bits.
 14. Tge driving device as claimed in claim 13, wherein the programmable resistor network (R_(Adj)) is connected to a monitor diode (700) of the light-emitting component (150).
 15. The driving device as claimed in one of the preceding claims 10 to 14, wherein the A/D converter (300) is connected to the negative input of the operational amplifier (600) and the programmable resistor network (R_(Adj)) is connected to the positive input of the operational amplifier (600).
 16. A method for driving a light emitting component (150), particularly a laser (150), in which an operating mode is selected from at least two different stored operating modes for driving the light-emitting component (150), and depending on the selected operating mode (B) and depending on the temperature (T) of the light-emitting component (150) or on a temperature proportional thereto, the component is driven with a predetermined operating-mode-and temperature-dependent bias current (I_(B)) and/or a predetermined operating-mode- and temperature-dependent modulation current (I_(M)).
 17. The method as claimed in claim 16, wherein the temperature (T) of the light-emitting component (150) or a temperature proportional to this temperature of the light-emitting component (150) is measured, forming a measured temperature value and the component is driven by using the measured temperature value.
 18. The method as claimed in claim 16 or 17, wherein a bias current value (I _(B)) for the bias current of the light-emitting current (150) and/or a modulation current value (I _(M)) for the modulation current (I_(M)) of the light-emitting component (150) is read out of a drive table in dependence on the measured temperature (T) and in dependence on the respective operating mode, and the light-emitting component (150) is driven with a bias current (I_(B)) corresponding to the bias current value (I _(a)) and/or a modulation current (I_(M)) corresponding to the modulation current value (I_(M)). 